Transposable mating type genes in Saccharomyces cerevisiae

A site-specific endonuclease essential for mating-type switching in Saccharomyces cerevisiae

We have detected two site-specific endonucleases in strains of Saccharomyces cerevisiae. One endonuclease, which we call YZ endo, is present only in yeast strains that are undergoing mating-type interconversion. The site at which YZ endo cleaves corresponds to the in vivo double-strand break occurring at the mating-type locus in yeast undergoing mating-type interconversion. YZ endo generates a site-specific double-strand break having 4-base 3' extensions terminating in 3' hydroxyl groups. The site of cleavage occurs in the Z1 region near the YZ junction of the mating-type locus. Mutant mating-type loci known to decrease the frequency of mating-type interconversion are correspondingly poor substrates for YZ endo in vitro. In vitro analysis of a number of such altered recognition sites has delimited the sequences required for cleavage. The molecular genetics of mating-type interconversion is discussed in the context of this endonucleolytic activity. The second endonuclease, which we refer to as Sce II, is present in all strains of S. cerevisiae we have examined. The cleavage site of Sce II has been determined and proves to be unrelated to the cleavage site of YZ endo.

The new yeast genetics

Gene cloning and yeast DNA transformation techniques have greatly enhanced the power of classical yeast genetics. It is now possible to isolate any classically defined gene, to alter the yeast genome at will by replacing normal chromosomal sequences with mutated derivatives produced in vitro, and to create DNA molecules that behave as autonomous replicons or minichromosomes. These unique features of the new yeast genetics have been used to study many problems in eukaryotic molecular biology.

Homologous and nonhomologous recombination in monkey cells

Though recombinational events are important for the proper functioning of most cells, little is known about the frequency and mechanisms of recombination in mammalian cells. We have used simian virus 40 (SV40)-pBR322 hybrid plasmids constructed in vitro as substrates to detect and quantitate intramolecular homologous and nonhomologous recombination events in cultured monkey cells. Excision of wild-type or defective SV40 DNAs by recombination from these plasmids was scored by the viral plaque assay, in either the absence or the presence of DNA from a temperature-sensitive helper virus. Several independent products of homologous and nonhomologous recombination have been isolated and characterized at the DNA sequence level. We find that neither DNA replication of the recombination substrate nor SV40 large T antigen is essential for either homologous or nonhomologous recombination involving viral or pBR322 sequences.

Efficient production of a ring derivative of chromosome III by the mating-type switching mechanism in Saccharomyces cerevisiae

The mating-type switches in the yeast Saccharomyces cerevisiae occur by unidirectional transposition of replicas of unexpressed genetic information, residing at HML or HMR, into the mating-type locus (MAT). The source loci, HML and HMR, remain unchanged. Interestingly, when the HM cassettes are expressed, as in marl strains, the HML and HMR cassettes can also efficiently switch, apparently by obtaining genetic information from either of the other two cassettes (Klar et al., Cell 25:517-524, 1981). We have isolated a novel chromosome III rearrangement in heterothallic (marl ho) strains, which is also produced efficiently in marl HO cells, presumably the consequence of a recombination event between HML and HMR. The fusion results in the loss of sequences which are located distal to HML and to HMR and produces a ring derivative of chromosome III. Cells containing such a ring chromosome are viable as haploids; apparently, no essential loci are located distal to the HM loci. The fusion cassette behaves as a standard HM locus with respect to both regulation by the MAR/SIR control and its role in switching MAT.

SAD mutation of Saccharomyces cerevisiae is an extra a cassette

Sporulation of Saccharomyces cerevisiae ordinarily requires the a1 function of the a mating type locus. SAD is a dominant mutation that allows strains lacking a1 (MAT alpha/MAT alpha and mata1/MAT alpha diploids) to sporulate. We provide functional and physical evidence that SAD is an extra cassette in the yeast genome, distinct from those at HML, MAT, and HMR. The properties of SAD strains indicate that the a cassette at SAD produces a limited amount of a1 product, sufficient for promoting sporulation but not for inhibiting mating and other processes. These conclusions come from the following observations. (i) SAD did not act by allowing expression of HMRa: mata1/MAT alpha diploids carrying SAD and only alpha cassettes at HML and HMR sporulated efficiently. (ii) SAD acted as an a cassette donor in HML alpha HMR alpha strains and could heal a mata1 mutation to MATa as a result of mating type interconversion. (iii) The genome of SAD strains contained a single new cassette locus, as determined by Southern hybridization. (iv) Expression of a functions from the SAD a cassette was limited by Sir: sir- SAD strains exhibited more extreme phenotypes than SIR SAD strains. This observation indicates that SAD contains not only cassette information coding for a1 (presumably from HMRa) but also sites for Sir action.

Structure and expression of genes for surface proteins in Paramecium

Surface proteins from 11 antigenic types of Paramecium tetraurelia vary in molecular weight from 251,000 to 308,000. The size of a series of polyadenylated RNAs obtained from these types were correlated with the sizes of the proteins and judged to be the mRNAs for the proteins. The mRNAs were used to identify genomic DNA clones containing complementary sequences. The gene for antigen A was present in one copy per genome, and the data suggest that extensive introns were absent. When restriction enzyme digests of DNA from cultures of paramecia with active and inactive genes were probed with portions of the cloned genes, no evidence for rearrangements or changes in gene dosage was found.

Deletions and single base pair changes in the yeast mating type locus that prevent homothallic mating type conversions

Several cis-acting mutations that prevent homothallic mating type conversions in Saccharomyces cerevisiae have been examined. Deletions within the mating type (MAT) locus were obtained by selecting for survivors among homothallic MAT alpha cells carrying the rad52 mutation. The survivors were unable to switch mating type, even in RAD+ derivatives. The deletions varied in size from fewer than 50 to more than 750 base pairs. All of the deletions removed a Hha I site at the border between the alpha-specific sequences (Y alpha) and the adjacent Z region. We also examined several spontaneous inc mutations that prevent MAT switching. Two of these mutations were cloned in recombinant DNA plasmids and their sequences were determined. The MAT alpha-inc 3-7 mutation proved to have an altered Hha I site at the Y alpha/Z border, by virtue of a single base pair substitution G . C leads to A . T in the second base pair of the Z region (Z2). Restriction fragment analysis showed that two other independently isolated strains with MAT alpha-inc mutations had altered the same Hha I site. The MAT a-inc 4-28 mutation contains a single base pair substitution C . G leads to T . A at position Z6. A base pair difference at position Z11 in two MATa strains does not affect MATa conversions. We conclude that the region near the Y/Z border is essential for the efficient switching of MAT alleles and constitutes an enzyme recognition site for a specific nucleolytic cleavage of MAT DNA.

Superunstable alleles at the cut locus in Drosophila melanogaster

This is a detailed study of the reversions of the ctMR2 allele putatively carrying á mobile element (MR-transposon) in the cut locus. Stable, unstable and superunstable revertants have been identified. Besides, a series of multiple unstable visible and lethal ct mutations derived from the ctMR2 allele have been obtained. They are shown to include supermutable alleles. The results suggest that the MR-transposon is connected with at least three functions: excision; change of orientation; and change of position within the cut locus, these functions being disturbed in different ways in different unstable ct+ and ct alleles. In some cases the mutant transitions are somehow strongly stimulated leading to superinstability, reaching the rate of 0.5.

Homologous and nonhomologous recombination in monkey cells

Though recombinational events are important for the proper functioning of most cells, little is known about the frequency and mechanisms of recombination in mammalian cells. We have used simian virus 40 (SV40)-pBR322 hybrid plasmids constructed in vitro as substrates to detect and quantitate intramolecular homologous and nonhomologous recombination events in cultured monkey cells. Excision of wild-type or defective SV40 DNAs by recombination from these plasmids was scored by the viral plaque assay, in either the absence or the presence of DNA from a temperature-sensitive helper virus. Several independent products of homologous and nonhomologous recombination have been isolated and characterized at the DNA sequence level. We find that neither DNA replication of the recombination substrate nor SV40 large T antigen is essential for either homologous or nonhomologous recombination involving viral or pBR322 sequences.

The widespread nature of phenotypic variability in hepatomas and cell lines, in the form of a geometric series

The phenomenon of geometric phenotypic variability is described and its widespread occurrence is established by a new analysis of data from a literature survey of quantitative variation in 39 different enzymes and other cell products in hepatomas and cell lines. The range of variation from hepatoma to hepatoma or from cell line to cell line was between 3- and 700-fold, depending on the particular cell product. By collating together and normalizing the data for the enzymes and other cell products surveyed, it was demonstrated in a statistically valid manner that the quantitative variation for most, if not all, of the enzymes and serum albumin was not random, but followed a geometric series, the consecutive terms of which differed by a factor of square root 2. In addition, examples are presented to show that quantitative inheritance in normal tissues also occurs along this geometric series.

Efficient production of a ring derivative of chromosome III by the mating-type switching mechanism in Saccharomyces cerevisiae

The mating-type switches in the yeast Saccharomyces cerevisiae occur by unidirectional transposition of replicas of unexpressed genetic information, residing at HML or HMR, into the mating-type locus (MAT). The source loci, HML and HMR, remain unchanged. Interestingly, when the HM cassettes are expressed, as in marl strains, the HML and HMR cassettes can also efficiently switch, apparently by obtaining genetic information from either of the other two cassettes (Klar et al., Cell 25:517-524, 1981). We have isolated a novel chromosome III rearrangement in heterothallic (marl ho) strains, which is also produced efficiently in marl HO cells, presumably the consequence of a recombination event between HML and HMR. The fusion results in the loss of sequences which are located distal to HML and to HMR and produces a ring derivative of chromosome III. Cells containing such a ring chromosome are viable as haploids; apparently, no essential loci are located distal to the HM loci. The fusion cassette behaves as a standard HM locus with respect to both regulation by the MAR/SIR control and its role in switching MAT.

SAD mutation of Saccharomyces cerevisiae is an extra a cassette

Sporulation of Saccharomyces cerevisiae ordinarily requires the a1 function of the a mating type locus. SAD is a dominant mutation that allows strains lacking a1 (MAT alpha/MAT alpha and mata1/MAT alpha diploids) to sporulate. We provide functional and physical evidence that SAD is an extra cassette in the yeast genome, distinct from those at HML, MAT, and HMR. The properties of SAD strains indicate that the a cassette at SAD produces a limited amount of a1 product, sufficient for promoting sporulation but not for inhibiting mating and other processes. These conclusions come from the following observations. (i) SAD did not act by allowing expression of HMRa: mata1/MAT alpha diploids carrying SAD and only alpha cassettes at HML and HMR sporulated efficiently. (ii) SAD acted as an a cassette donor in HML alpha HMR alpha strains and could heal a mata1 mutation to MATa as a result of mating type interconversion. (iii) The genome of SAD strains contained a single new cassette locus, as determined by Southern hybridization. (iv) Expression of a functions from the SAD a cassette was limited by Sir: sir- SAD strains exhibited more extreme phenotypes than SIR SAD strains. This observation indicates that SAD contains not only cassette information coding for a1 (presumably from HMRa) but also sites for Sir action.

The alternate expression of two restriction and modification systems

Plasmids R124 and R124/3 carry genes coding for two different R-M systems and normally only one set of genes is expressed. These genes can be translocated to F plasmids that are compatible with the R factors and in strains carrying these F plasmids and an R factor a transacting regulatory mechanism switches off the expression of R-M genes on the introduced plasmid. Additionally the unexpressed genes on the introduced plasmid are expressed. The regulatory mechanism controlling the alternative expression of R124 and R124/3 R-M genes involves a physical rearrangement of DNA sequences.

Structure and expression of genes for surface proteins in Paramecium

Surface proteins from 11 antigenic types of Paramecium tetraurelia vary in molecular weight from 251,000 to 308,000. The size of a series of polyadenylated RNAs obtained from these types were correlated with the sizes of the proteins and judged to be the mRNAs for the proteins. The mRNAs were used to identify genomic DNA clones containing complementary sequences. The gene for antigen A was present in one copy per genome, and the data suggest that extensive introns were absent. When restriction enzyme digests of DNA from cultures of paramecia with active and inactive genes were probed with portions of the cloned genes, no evidence for rearrangements or changes in gene dosage was found.

One-step gene disruption in yeast

The one-step gene disruption techniques described here are versatile in that a disruption can be made simply by the appropriate cloning experiment. The resultant chromosomal insertion is nonreverting and contains a genetically linked marker. Detailed knowledge of the restriction map of a fragment is not necessary. It is even possible to "probe" a fragment that is unmapped for genetic functions by constructing a series of insertions and testing each one for its phenotype.

Genetic applications of yeast transformation with linear and gapped plasmids

Techniques for high frequency yeast transformation have been described. A double-strand break introduced by restriction enzyme cleavage can be used to direct a plasmid to integrate into a particular chromosomal locus. Plasmids containing a double-strand gap can be used in a straightforward method for the isolation and mapping of chromosomal alleles. These techniques extend the genetic applications of yeast transformation.

Homothallic switching of yeast mating type cassettes is initiated by a double-stranded cut in the MAT locus

A double-stranded DNA cut has been observed in the mating type (MAT) locus of the yeast Saccharomyces cerevisiae in cultures undergoing homothallic cassette switching. Cutting is observed in exponentially growing cells of genotype HO HML alpha MAT alpha HMR alpha or HO HMLa MATa HMRa, which switch continuously, but not in a/alpha HO/HO diploid strains, in which homothallic switching is known to be shut off. Stationary phase cultures do not exhibit the cut. Although this site-specific cut occurs in a sequence (Z1) common to the silent HML and HMR cassettes and to MAT, only the Z1 sequence at the MAT locus is cut. The cut at MAT occurs in the absence of the HML and HMR donor cassettes, suggesting that cutting initiates the switching process. An assay for switching on hybrid plasmids containing mata- cassettes has been devised, and deletion mapping has shown that the cut site is required for efficient switching. Thus a double-stranded cut at the MAT locus appears to initiate cassette transposition-substitution and defines MAT as the recipient in this process.

Transposition of yeast mating type genes from two translocations of the left arm of chromosome III

In the yeast Saccharomyces cerevisiae, the HIS4C gene lies on the left arm of chromosome III. We analyzed two chromosomal rearrangements that have HIS4C translocated either to chromosome XII or to a new translocation chromosome. Using the cmt mutation that allows expression of the normally silent copies of mating type genes, we found that both of these translocations also carried HML alpha, more than 30 map units distal to HIS4C which normally lies on chromosome III. In the case of the translocation chromosome (designated T3), we also found an exchange event between HML alpha on the translocation chromosome and HMLa on chromosome III. In diploids containing two T3 chromosomes (one carrying HML alpha and the carrying HMLa), we found that HML was 32 centimorgans from HIS4C, which was 10 centimorgans from an unknown centromere. In homothallic strains carrying HMLa MATa HMRa on chromosome III, switching from MATa to MAT alpha could occur by using the HML alpha on the translocation as the sole donor of alpha information. Transposition from HML alpha on chromosome T3 was about 20 to 40% as efficient as transposition from intact chromosome III. In contrast, transposition from the HML alpha inserted into chromosome XII was reduced about 100-fold. This reduced efficiency did not appear to be caused by an alteration in the sequences immediately surrounding HML alpha in the translocation. The translocated HML alpha sequence was located in the same size (29-kilobase) SalI fragment as was found in chromosome III, and the same EcoRI, HindIII, and BglII restriction sites were also found. Furthermore, HML alpha was still under the control of the CMT gene, which maintains HML as a silent copy of mating type information. These results suggested that the position of the HML alpha sequence plays an important role in the efficiency of mating type switching.

Possible mechanism for flocculation interactions governed by gene FLO1 in Saccharomyces cerevisiae

A model is proposed for the mechanism of flocculation interactions in yeasts in which flocculent cells have a recognition factor which attaches to alpha-mannan sites on other cells. This factor may be governed by the expression of the single, dominant gene FLO1. Isogenic strains of Saccharomyces cerevisiae, differing only at FLO1 and the marker genes ade1 and trp1, were developed to examine the components involved in flocculene. Electron microscopy and concanavalin Aferritin labeling of aggregated cells showed that extensive and intense interactions between cell wall mannan layers mediated cell aggregation. The components of the mannan layer essential for flocculence were Ca2+ ions, alpha-mannan carbohydrates, and proteins. By studying the divalent cation dependence at various pH values and in the presence of competing monovalent cations, flocculation was found to be Ca2+ dependent; however, Mg2+ and Mn2+ ions substituted for Ca2+ under certain conditions. Reversible inhibition of flocculation by concanavalin A and succinylated concanavalin A implicated alpha-branched mannan carbohydrates as one essential component which alone did not determine the strain specificity of flocculence, since nonflocculent strains interacted with and competed for binding sites on flocculent cells. FLO1 may govern the expression of a proteinaceous, lectin-like activity, firmly associated with the cell walls of flocculent cells, which bind to the alpha-mannan carbohydrates of adjoining cells. It was selectively and irreversibly inhibited by proteolysis and reduction of disulfide bonds. The potential of this system as a model for the genetic and biochemical control of cell-cell interactions is discussed.

Chromosomal rearrangement and carcinogenesis

All carcinogens that have been thoroughly tested have been found to induce some kind of chromosomal rearrangement. Chromosomal rearrangements are associated with a variety of human and rodent cancers and are associated, with in vitro cell transformation. The DNA from non-malignant cells can transform other non-malignant cells under conditions that may involve chromosomal rearrangement. These findings support the view that chromosomal rearrangement can be a step in carcinogenesis. Available evidence indicates that carcinogens can act to induce chromosomal rearrangement by creating or revealing sites on DNA for recombination, or by inducing or activating cellular systems resulting in a stimulation of recombination. Chromosomal rearrangement may affect carcinogenesis by altering gene expression. Perhaps by allowing the activation of cellular cancer genes.

Changes in production of the mating-type-specific glycoproteins, agglutination substances in association with mating type interconversion in homothallic strains of the yeast, Saccharomyces cerevisiae

Sexual activity in homothallic strains of Saccharomyces cerevisiae was investigated. We succeeded in culturing homothallic haploid cells without conjugation, by lowering the pH value of the culture medium. In spore cultures of a homothallic strain both a and alpha pheromones were detected. Agglutination substance of a and alpha mating types were detected in homothallic haploid cells from spore cultures in early logarithmic phase regardless of mating type information at the HML and HMR loci, but either a or alpha agglutination substance was detected predominantly in homothallic haploid cells from spore culture in late logarithmic phase, depending on mating type information at the HML and HMR loci.

Directionality of yeast mating-type interconversion

The mating-type a and alpha alleles of the yeast Saccharomyces cerevisiae interconvert by a transposition-substitution reaction where replicas of the silent mating loci, at HML and HMR, are transmitted to the expressed mating-type locus (MAT). HML is on the left arm and HMR on the right arm, while MAT is in the middle of chromosome III. Cells with the genotype HML alpha HMRa switch mating type efficiently at a frequency of about 86%. Since well over 50% of the cells switch, it is thought that switches do not occur randomly, but are directed to occur to the opposite mating-type allele. In contrast, we report that strains possessing the reverse HMLa HMR alpha arrangement switch (phenotype) inefficiently at a maximum of about 6%. The basis for this apparent reduced frequency of switching is that these strains preferentially yield futile homologous MAT locus switches--that is, MATa to MATa and MAT alpha to MAT alpha--and consequently, most of these events are undetected. We used genetically marked HM loci to demonstrate that alpha cells preferentially choose HMR as donor and a cells preferentially choose HML as donor, irrespective of the genetic content of the silent loci. Because of this feature, HML alpha HMRa strains generate predominantly heterologous while HMLa HMR alpha strains produce predominantly homologous MAT switches. The control for directionality of switching therefore is not at the level of transposing heterologous mating-type information, but only at the level of choosing HML versus HMR as the donor. In strains where the preferred donor locus is deleted, the inefficient donor becomes capable of donating efficiently. Thus the preference seems to be mediated by competition between the HM loci for donating information to MAT.

Transposition of yeast mating type genes from two translocations of the left arm of chromosome III

In the yeast Saccharomyces cerevisiae, the HIS4C gene lies on the left arm of chromosome III. We analyzed two chromosomal rearrangements that have HIS4C translocated either to chromosome XII or to a new translocation chromosome. Using the cmt mutation that allows expression of the normally silent copies of mating type genes, we found that both of these translocations also carried HML alpha, more than 30 map units distal to HIS4C which normally lies on chromosome III. In the case of the translocation chromosome (designated T3), we also found an exchange event between HML alpha on the translocation chromosome and HMLa on chromosome III. In diploids containing two T3 chromosomes (one carrying HML alpha and the carrying HMLa), we found that HML was 32 centimorgans from HIS4C, which was 10 centimorgans from an unknown centromere. In homothallic strains carrying HMLa MATa HMRa on chromosome III, switching from MATa to MAT alpha could occur by using the HML alpha on the translocation as the sole donor of alpha information. Transposition from HML alpha on chromosome T3 was about 20 to 40% as efficient as transposition from intact chromosome III. In contrast, transposition from the HML alpha inserted into chromosome XII was reduced about 100-fold. This reduced efficiency did not appear to be caused by an alteration in the sequences immediately surrounding HML alpha in the translocation. The translocated HML alpha sequence was located in the same size (29-kilobase) SalI fragment as was found in chromosome III, and the same EcoRI, HindIII, and BglII restriction sites were also found. Furthermore, HML alpha was still under the control of the CMT gene, which maintains HML as a silent copy of mating type information. These results suggested that the position of the HML alpha sequence plays an important role in the efficiency of mating type switching.

A position-effect control for gene transposition: state of expression of yeast mating-type genes affects their ability to switch

Mating-type switches of the yeast Saccharomyces cerevisiae occur by unidirectional transposition of copies of unexpressed mating-type genetic information, residing at HML and HMR loci, into the expressed MAT locus. The HML and HMR loci remain unchanged. In contrast, in appropriate strains where the silent loci are also allowed to express, for example in mar mutants, efficient switches of HML and HMR are shown to occur at rates equivalent to those observed for MAT. Thus the position-effect control on the direction of transposition is affected by the state of expression of the locus under study the expressed loci switch regardless of their location.

Gene conversion between duplicated genetic elements in yeast

The mitotic recombination behaviour of a duplication of the his4 region on chromosome III in the yeast Saccharomyces cerevisiae was studied. The major recombination event between the duplicated segments is gene conversion unassociated with reciprocal recombination. The rad52-1 mutation preferentially decreases mitotic gene conversion. These results suggest that mitotic gene conversion may occur by a different pathway from that occurring in meiosis. This mitotic gene conversion may be important in yeast mating type interconversion and the maintenance of sequence homogeneity in families of repeated eukaryotic genes.